SE528601C2 - Heat pump system used with domestic hot-water supply system of building or heating installation of swimming pool, has control system, that includes opening, fan, air duct and damper, which regulates flow of outdoor air to external space - Google Patents

Abstract

An external space (2) allows heating of outdoor air using solar radiation (12). The outdoor air is conducted to a heat pump (5) via the external space. A control system regulates the flow of outdoor air to the external space. The control system includes an opening (3), a fan (6), an air duct (7) and a damper (9). The heat pump receives thermal energy from the outdoor air and transfers the thermal energy to a water flow (20).

Description

fszs eo1 2 boreholes ("rock heat"), outdoor air and exhaust air (ie air that is ventilated out of a building) and emit heat to, for example, indoor air or water treatment.

Heat pumps have for a long time also been used for cooling buildings in the form of air conditioning systems where you take heat from a building and emit it outdoors. A heat pump needs electricity to drive the compressor, which is why the price of electricity is an important parameter for a heat pump's economic profitability. In colder climates, the effect of a heat pump is normally not sufficient to cope with heating on its own, which is why buildings are equipped with additional heating systems.

To further improve the efficiency of heating systems, it is common to try to utilize solar radiation. One example is allowing water to circulate in a solar-powered system in order to receive a "free" contribution to the production of hot water. Another example is given in an outdoor air defense pump is located in a windowed attic space which allows heating of the outdoor air by solar radiation.

In recent years, the development has focused a lot on heat pump components and refrigerants, e.g. in order to make outdoor air heat pumps efficient at ever lower outdoor temperatures.

DISCLOSURE OF THE INVENTION An object of the present invention is to further improve the efficiency of a heat pump system comprising an outdoor air heat pump or the like.

This object is achieved m.h.a. the technical features of claim 1. The dependent claims state advantageous embodiments, developments and variations of the invention.

The invention relates to a heat pump system comprising a heat pump arranged to allow uptake of friend energy from outdoor air and emission of heat energy to another medium, and an outer space adapted to allow heating of the outdoor air by utilizing solar radiation, wherein the system is US4378787 that lead the outdoor air to the friend pump via the outer space. The invention is characterized in that the heat pump system comprises means for regulating the fate of the outdoor air to the outer space. In other words, the system includes means for, if necessary, increasing or decreasing the ventilation / air exchange in the outer space. An advantageous effect of this construction is that by regulating the temperature of the outdoor air, the temperature in the outer space can be regulated, which in turn can be used to increase the efficiency of the friend pump. In a first example one can minimize to the till fate of outdoor air, i.e. allow the air to recirculate in the outer space, as long as the temperature in the outer space, thanks to radiated solar energy, is higher than in the surrounding outdoor air. In most situations, this has a positive effect on the friend pump's efficiency. In a second example, it is possible to maximize to the fate of outdoor air when the temperature in the outer space is lower, or is about to become lower, than the temperature in the ambient air, which can occur when the radiated amount of friend is less than the friend pump's inner outlet. Thanks to the inventive solution, the temperature in the outer space can be prevented from falling lower than the outdoor air temperature. This avoids a situation where the heat pump's efficiency is reduced due to that it is forced to work with cooled outdoor air. which can occur, for example, with a construction according to US4378787 where means are lacking for controlling the air exchange in the outer space.

The heat energy that is transferred to the other medium according to the invention can e.g. be used for heating a tap water system in an adjacent building or for heating a facility such as a swimming pool.

In a first preferred embodiment of the invention, the heat pump system comprises a first shaft arranged to create a supply of outdoor air to the outer space. This provides a prerequisite for simple and efficient regulation of fate. Preferably, the fl spout is arranged to create a from fl desert of air from the outer space and furthermore the system suitably comprises an inlet which allows for the fl desert of outdoor air to the outer space.

In this way, the property indirectly creates a supply of outdoor air to the outer space: S28 601 4 at the same time as it provides increased opportunities to control which air is to leave the outer space. The fan may very well be an integral part of the heat pump, which allows the use of many conventional outdoor air heat pumps. In a second preferred embodiment of the invention, the fate control medium is arranged to direct a fate of air contacted with the heat pump and to allow the distribution of said air fate between a first outlet, located inside the outer space, and a second outlet located outside the outer space. Since the air contacted with the heat pump has given off heat to the other medium, this air will normally be colder than other air in the outer space. The possibility of being able to distribute this air fate in the manner described gives increased opportunities to regulate the temperature in the outer space. For example, in order to avoid a lowering of the temperature in the outer space, the air in the outer space can be recirculated when the lult fl fate is warmer than the outdoor air and the air sound can be led out directly when the lult fl fate is colder than the outdoor air. Preferably, the fate control medium comprises an air duct for directing the fate of air contacted with the heat pump and a valve device arranged to allow a controllable distribution of said air between a first outlet duct, which opens inside the outer space, and a second outlet duct, the outer mouth. the space. It is then convenient to place the first fl pair adjacent to the air duct. In a third preferred embodiment of the invention, the friend pump system is arranged in connection with a building and further the friend pump system comprises a connecting duct arranged to conduct air between the outer space and the building. An advantageous effect of this design is that the air in the outer space can be led into the building, as well as that the air in the building can be led to the outer space. Since the combination of the heat pump and the regulation of the air supply to the outer space allows the air to be tempered in the outer space, the renewable r528 601 system can not only supply heat energy via the heat pump but also supply temperate air to the building. An example is when there is a cooling need in the building, e.g. a won summer day in Sweden, when you can let the heat pump take friend from the outer space and give tlll e.g. a tap water system in the building. The air temperature can then be lowered into the outer space. When this temperature is sufficiently low, lower than both the outdoor temperature and the indoor temperature in the building, the inventive system allows the cooled air to be led from the outer space into the building via the connecting duct. Something similar is not possible for a conventional outdoor air friend pump that is normally mounted on a house wall without even having any space to temper the outdoor air in. Another example is when there is a need to get used to it in the building. Correspondingly, the solar radiation can be allowed to heat the air sufficiently in the outer space to then lead the air directly into the building. The inventive solution also allows, by changing the direction of fate through the connecting duct and directing exhaust air from the building to the outer space. that the friend in the exhaust air can be used by the heat pump. Preferably, the heat pump system comprises means for regulating the air flow through the connecting duct, such as e.g. a second fl shaft and / or a valve located adjacent to the connecting duct.

In a fourth preferred embodiment of the invention, the heat pump system comprises an adjustable solar cutting device adapted to be able to sense the solar radiation and thereby limit the heating of the outdoor air in the outer space. This provides additional opportunities to regulate the temperature in the outer space.

DESCRIPTION OF THE FIGURES The invention is described below with reference to the following figures: Figure 1 which schematically shows a preferred embodiment of the invention. 528 601 PREFERRED EMBODIMENTS Figure 1 schematically shows a preferred embodiment of a heat pump system 10 according to the invention. A heat pump 5 is arranged to absorb thermal energy from outdoor air from an outer space 2 adapted to allow heating of the outdoor air by solar radiation 12 and to deliver heat energy to a building 4 by heating water. The outer space 2 can consist of a greenhouse, a glass dome, a glazed yard or other glazed construction at or adjacent to the wall 8 or roof of the building 4.

The heat pump 5 conventionally comprises a number of components in the form of an evaporator, a compressor, a condenser. an expansion valve and a refrigerant duct to guide around a refrigerant (which components are not shown in the fi clock). The heat pump 5 is in turn arranged in or adjacent to both the outer space 2 and the building 4 in such a way that the air in the outer space 2 is contacted with the heat pump's evaporator and so that a fl fate of water in the building 4 is contacted with the heat pump condenser. The heat absorbed from the outdoor air in the evaporator can then be given off to Vatten fl ödet 20 in the condenser. The water flow 20 can, directly or indirectly via heat exchange, be intended for use in a water-borne recovery system (not shown) or for the recovery of tap water. The thermal energy absorbed in the Water fl destiny 20 does not, of course, need to be used directly but can be used to create a reservoir of hot water for later use. Walls and ceilings 13 in the outer space 2 are largely made of glass to allow the solar radiation 12 to heat air contained inside the outer space 2. The sun-irradiated wall 8 and the floor 1 of the outer space 2 are coated or made of a heat accumulating material 18 such as stone or concrete. The outer space 2 is also provided with a solar shading device in the form of blinds 14 in order to enable limitation of irradiated amount of solar energy. A first fl shaft 6 is arranged adjacent to the friend pump 5 in order to force air to be contacted with the heat pump 5. The first fl shaft 6 is normally always switched on during operation of the heat pump 5. Furthermore, an air duct 7 is arranged adjacent to the first och shaft 6 and friend pump 5 in such a way that the air which has passed the heat pump 5 is led into the air duct 7. The air duct 7 branches 528 601 7 a bit downstream and forms a first outlet duct 7a which allows discharge of the air inside the outer space 2 and a second outlet duct 7b which leads the air out of the outer space 2. A valve device in the form of a damper 9 is placed at the branch in order to regulate the air flow between the first and the second outlet duct 7a, 7b depending on the operating situation. Outdoor air is supplied to, or possibly removed from, the outer space 2 via an opening 3 adapted to allow flow of air when a pressure difference arises between the outdoor air and the air in the outer space 2, e.g. then the air contacted with the heat pump 5 is led out of the outer space 2 via the second outlet duct 7b. By choosing a distribution between the outlet ducts 7a, 7b, it is thus possible to regulate the flow of outdoor air to the outer space 2. The heat pump system 10 is further provided with a connecting duct 15 intended to direct air between the outer space 2 and the building 4 in certain operating situations. 15 is provided with a valve 17 and a second fan 16 for regulating the air flow between the outer outer space 2 and the building 4. A number of arrows 1 show some different paths through which the air can flow. In addition to what has already been described above, said arrows show that the air enters the heat pump 5 on the side of the heat pump 5 which faces the house wall 8.

For the following description of operating examples for the heat transfer system 10, the designations T1, T2 and T3 have been entered in Figure 1, where T1 refers to the outdoor air temperature, T2 refers to air temperature the outer space 2, and T3 refers to the indoor air temperature in the building 4. The temperature T2 in the outer space 2 can of course vary between different positions in space 2. Unless otherwise stated, T2 refers to a kind of average temperature, for example measured in connection with the inlet of air to the friend pump. To determine the temperatures, one of your well-known types of temperature sensors is suitably used.

The heat pump system 10 can operate in different ways depending on the prevailing conditions. Examples of more important conditions are the building's 4 cooling-light requirements, the outdoor air temperature T1, and the current intensity for solar radiation. In a conventional manner, the building 4 may very well be equipped with complementary heating and cooling systems.

However, the presence of such systems does not in principle affect the operation of the inventive heat pump system 10.

Operating situation In a first example of an operating situation, there is a need for heating of the indoor air in building 4. Normally, T1 is lower than a desired value of T3.

A typical example of such a situation is a home in Sweden during a colder part of the year. In this situation the solar cut-off device 14 is kept, during the day, in an open position and the friend pump 5 is allowed to deliver as much heat as possible to the water 20 in the building 4. In an initial stage the valve 17 can be kept closed and the damper 9 be in such a position the first outlet duct 7a so that in principle No outdoor air is supplied to the outer space 2. Depending on e.g. taken effect of the friend pump 5, the volume of the outer space 2, temperature of outdoor air T1, outlet temperature T2 in the outer space and current solar radiation 12, the air temperature T2 in the outer space 2 will rise. kept constant or falling.

Unless the temperature T2 is higher than T3. and especially if T2 is also rising. the valve 17 can be opened so that heated air can flow through the connecting duct 15 from the outer space 2 into the building 4. Suitably the second fl shaft 16 is used to increase fl the fate. The valve 17 and the spout 16 can be closed e.g. when the temperature T2 has dropped to the same level as T3. As an alternative, or complement. to allow the heated air to be supplied into the building 4 through the connecting duct 15, the damper 9 can be set in a position so that the air at least partially flows through the second outlet duct 7b.

This measure allows air exchange in the outer space 2, which in turn allows the temperature T2 to be lowered (provided that T1 is lower than T2). This may be suitable for the purpose of allowing the friend pump 5 to operate in a certain temperature range or to keep the temperature in the outer space 2 below a certain temperature for some other reason such as e.g. that the outer space 2 contains temperature-sensitive plants.

Unless the temperature T2 is lower than T1. or when T2 drops lower than T1, the position of the damper 9 is changed so that the air leaving the friend pump 5 is led out via the second outlet duct 7b. Since the air contacted with the friend pump 5 has given off heat to the water 20, this air will be colder than T2. By this measure, outdoor air with the temperature T1 will flow in through the opening 3 and raise T2, unless other conditions, such as solar radiation and power output, are the same. With a sufficiently large air exchange, an operating mode is obtained where T2 will be equal to T1. With a good air circulation in the outer space 2, the temperature T2 in the outer space 2 will thus at least go down to the outdoor temperature T1. If this minimum temperature is lower than desirable in view of the efficiency of the heat pump 5, it may be appropriate to reduce the power of the heat pump 5 slightly so that the air has time to be heated sufficiently by the solar radiation. Typically, such a situation can prevail on a cold and sunny winter day. In a variant of the invention, a temperature T4 is also determined in the (colder) air flow leaving the heat pump 5, e.g. in a position far upstream of the air duct 7. Since the air leaving the friend pump 5 has given off heat to the water 20 20, T4 will normally be lower than T2. To keep T2 as high as possible, the system 10 can be controlled in such a way that when T4 is lower than T1, but where T2 can be higher than T1, the position of the damper 9 is changed so that the air is led out of the outer space 2 via the second outlet duct 7b. In this way, the outer space 2 is supplied with more water than if the air were to be circulated via the first outlet duct 7a and thereby, for example, it is possible to avoid that T2 sinks lower than T1.

Suitably the solar cut-off device 14 is set to the closed position when the solar radiation is negligible, i.e. night time and possibly very dark t528 601 days. Then the heat radiation from the outer space 2 is reduced. An additional temperature-raising effect can be obtained by ensuring that the outer space 2 is well heat-insulated. Heat leakage from the heat pump 5's compressor, the building 4 or other sources that are delivered to the outer space 2 can then be utilized in a better way. If you instead wish to cool the air in the outer space, see below, you should preferably let the friend from the heat pump's compressor 5 be led out outside the outer space 2.

Operating situation B In a second example of an operating situation, there is a need for cooling of the indoor air in building 4. Normally, T1 is higher than a desired value of T3. At the same time, there is a need to adapt the water 20 to the production of tap water.

A typical example of such a situation is a home in Sweden during the summer, especially during the day but sometimes also at night. In this situation, the purpose is to allow the heat pump 5 to create cold air in the outer space 2 for cooling the building 4 at the same time as, according to previous friends, the water 20 desolation 20.

The solar shielding device "14 can be kept in a closed position, at least during the day, to minimize the radiation from the sun. Depending on the intensity of the solar radiation 12 and the heat outlet of the heat pump 5, the degree of opening of the solar shielding device 14 can be regulated. In the initial stage, the damper 9 is set in such a position that the air is led via the first outlet duct 7a at the same time as the valve 17 is kept closed so that in principle no exchange of air takes place in the outer space 2. Due to the heat pump 5 absorbing heat energy from the air in the outer space 2, the temperature T2 will gradually decrease, and when the temperature T2 has become lower than both T1 and T3, the building 4 can be cooled by directing air from the outer space 2 to the building 4 through the connecting duct 15 by opening the valve 17. Preferably the second fl marriage 16 is used to increase the fl fate of the supply air, outdoor air will then flow in n to the outer space 2 via the opening 3. Depending on e.g. outdoor temperature fi T1, heat outlet and current solar radiation, the air temperature T2 in the outer space 2 will now rise, be kept constant or fall further. In order to find a stable operating position in this situation, it is possible, for example, to regulate the degree of opening of the valve 17 and the solar sensing device 14, and / or the power of the other 16 shaft 16. If the temperature T2 in the outer space 2 still rises, in order to lower T2, it may be necessary to completely close the valve 17 and the solar cut-off device 14. In another variant of the invention, the heat pump system 10 can be provided with a further channel (not shown) adapted to conduct air which is contacted with the friend pump 5 directly to the connecting duct 15. As mentioned above, this air is normally colder than the temperature T2. It is suitably allowed to dehumidify the air flow through the said further channel before entering the building 4. Also in this variant it is suitable to determine the temperature T4 in the (colder) air flow leaving the heat pump 5, e.g. in a position far upstream of the air duct 7. in order to be able to determine how the system 10 is to be controlled. With this variant of the invention it is possible to obtain a faster flow of air with a sufficiently low temperature to cool the building 4. For example, this additional duct can consist of a branch of the first outlet duct 7a van / id an additional damper (not shown) is suitably set up. for distributing the air flow between the first outlet duct 7a and said further duct. In an example of this second operating situation, in an initial stage the outdoor air temperature is T1 = 25 ° C, the temperature of the outer space 2 T2 = 25 ° C, and the indoor air temperature T3 = 24 ° C. The desired indoor temperature, i.e. the desired value of T3, is 21 ° C. As described above, T2 will gradually decrease as the heat pump system 10 operates. When T2 is lowered to e.g. At 23 ° C, air can be led into the building 4 via the connecting duct 15. As long as T2 is lower than T3 and T3 is higher than 21 ° C, this can continue. Alternatively, one can wait to lead air into the building via the connecting duct 15 to T2 become e.g. 20 ° C. lszs 601 12 The outer space 2 can be designed in many different ways. Preferably, most, or at least a large part, of its walls and / or its roof are formed of glass or some other material transparent to solar radiation.

The term "transparent" in this context means that the material is sufficiently transparent for a sufficiently large part of the wavelength spectrum of solar radiation for air or other material inside the transparent material to be heated. Conventional window glass can be used, for example. Plastic materials also work well provided they are sufficiently durable. Preferably, so-called energy-saving glass which, to a greater extent than conventional window glass, reflects long-wave heat radiation back to the outer space 2 and transmits the more short-wave solar energy.

The transparent parts should be directed at a suitable angle to the sky so that an efficient irradiation of solar energy is achieved. In the northern hemisphere, moreover, the transparent parts should of course have a main direction to the south. In addition to what has been mentioned above, the outer space 2 can consist of (parts of) an entire glazed façade. For example, a larger office building can be provided with a number of external spaces 2 arranged inside a fully glazed southern façade.

Furthermore, the outer space 2 may contain means for increasing the absorption of the solar radiation, such as black-painted surfaces and friend-accumulating materials 18 such as e.g. stone and concrete. The outer space may also contain agents such as e.g. fl genres and guide plates for circulating and conducting air within the outer space 2. Such means make it possible to achieve an even temperature distribution in the outer space 2. As previously mentioned, the system is set up in such a way that, in order to keep the temperature T2 so high as possible, air contacted with the heat pump 5 can be led directly out via the second outlet duct 7b to prevent it from mixing with the other, normally slightly warmer, air in the outer space 2. Furthermore, one can choose that, in order to keep the temperature T2 as low as possible, design the system 10 so that you can discharge the air that is at the top of the outer space 2, which air is normally the warmest. Furthermore, the outer space 2 may contain dehumidifiers, air filters, etc. for air treatment. Preferably, the outer space 2 is arranged to have a good thermal insulation so that the temperature in 528 601: 13 T2 in the outer space 2 is determined as much as possible by radiated solar energy, air exchange (via ducts 7b, 15 and opening 3) and the outlets. heat from the heat pump 5. In this way the energy is used better and in addition this means that the heating system 10 can be controlled in a better way.

What volume the outer space 2 should suitably have depends on fl your factors such as design of the outer space 2, the heat pump's 5 power, which climate zone the building is located in and the building's 4 heating / cooling needs. For a normal-sized villa located in Sweden and a conventional outdoor air heat pump, it works well with an ordinary greenhouse, i.e. somewhere around 30 m ”. But even larger or smaller volumes are conceivable.

The heat pump system 10 according to the invention works excellently with an outdoor air shock pump of a conventional type with regard to e.g. power and appropriate temperature range. In addition, such heat pumps are usually equipped with a built-in drive which can act as the first drive 6 specified in lug 1.

To regulate the heat pump system 10 according to the invention, a number of parameters may be of interest depending on how advanced control system one wants: outdoor air temperature T1, air temperature in the outer space T2, air temperature in the building T3, temperature of the air contacted with the heat pump T4, friend heat power output, intensity of solar radiation 12; opening position on dampers / valves 9, 17 and solar cut-off device 14, power position for fl spouts 6, 16 and power requirement for water 20. fate 20. The outdoor air pressure, in the outer space 2 and in the building 4 can also be used for regulation, especially if the opening 3 is provided with a controllable valve.

Preferably, the system 10 is provided with a number of temperature, radiation, position sensors, etc. to be able to determine the desired parameters and further provided with operating means for changing settings. Of course, it is possible for a person skilled in the art, with the information given in this text, to automate the control of the heat pump system 10 in a manner similar to conventional heating or ventilation systems.

Preferably, the control of the heat pump system 10 is integrated with other important ventilation and heating systems in the building 4.

The system further provides the possibility of directing air from the building 4 to the outer space 2 through the connecting duct 15. for example by driving the second fl marriage 16 backwards (which fl marriage 16 then has a function as exhaust air fl marriage instead of supply air fl marriage). This can e.g. be suitable In order to take care of the friend in the building's 4 air.

The invention is not limited to the embodiments described above but can be modified within the scope of the appended claims. For example, at least some of the advantages of the invention can be utilized even if the lull contacted with the friend pump 5 cannot be led directly out, which in the described example according to figure 1 is achieved by means of the first fl 6 and the air duct 7 together with its second outlet duct 7b. The basis is to have a good regulation of the air exchange in the outer space 2. instead of the air duct 7 and its outlet 7a, 7b would e.g. a releasable additional fl can be placed in a further opening so as to allow adjustable air exchange in the outer space 2. In such a variant the air contacted with the heat pump 5 is thus mixed with other air in the outer space 2. An essential advantage in The embodiment described in Figure 1 is, however, as mentioned above, that it allows a more efficient temperature control by the possibility of directing the colder air contacted with the heat pump 5 directly out, or directly to the connecting duct, without first mixing. with the design according to it Fans, dampers, valves, ducts and openings can of course be arranged in alternative ways than what is schematically shown in Figure 1. For example, the damper 9 can be replaced with a valve 1 each outlet duct 7a, 7b. Furthermore, the channels 7, 7a, 7b can be placed outside the outer space 2; the important thing is of course where its inlets and outlets are located. the opening 3 can of course have 528,601 alternative locations. The size of the opening 3 is not critical but it should be large enough not to prevent air from flowing in or out of the outer space 2 as this is desirable and small enough to minimize unwanted air flow. Of course, your openings can be used. Furthermore, the opening 3 can be provided with both a valve and a fl genuine if desired.

Building 4 can be a residential or office building or some other form of premises. Furthermore, it is not necessary that fl fate 20 consists of water; it may be another medium which absorbs the heat energy from the heat pump 5.

Of course, it is also not necessary for the entire heat energy to be absorbed by the building 4; for example, one or fl your surrounding buildings or facilities such as swimming pools, heated sidewalks or roads, agricultural facilities or industrial processes can use this friend energy. Thus, it is not necessary that the friend pump system 10 be arranged in connection with a building; for example, the system 10 with associated outer space 2 can constitute a separate unit arranged in connection with e.g. a swimming pool. However, in order to utilize the advantageous cooling function via the connecting duct 15, it is extra favorable that the system 10 is arranged in connection with a building which at least sometimes has a cooling need.

In the case of the sun protection device 14, this, as an alternative to blinds, can for instance consist of cloths which are pulled back and forth, or down and up. Furthermore, it is not necessary to place the sun protection device 14 inside the outer space 2; from a shading point of view, it may be advantageous to place it externally, for example in the form of an awning-like device. On the other hand, an externally placed sun protection device 14 is more exposed to weather and wind, which can affect its function. Preferably, the sun protection device 14 is motor driven to facilitate automatic control.

Claims (12)

10 15 20 25 30 528 601 16 PATENT REQUIREMENTS A heat pump system (10) comprising: - a friend pump (5) arranged to allow uptake of thermal energy from outdoor air and discharge of heat energy to another medium (20), and - an outer space (2) adapted to allow heating of the outdoor air by utilization of solar radiation (12), wherein the system (10) is arranged to lead the outlet to the heat pump (5) via the outer space (2), characterized in that the heat pump system (10) comprises means (3, 6, 7, 7a, 7b, 9 ) to regulate the fate of the outdoor air to the outer space (2). Heat pump system (10) according to claim 1, characterized in that the system (10) comprises a first fl genuine (6) arranged to create a supply of outdoor air to the outer space (2). Heat pump system (10) according to claim 2, characterized in that the first fl spout (6) is arranged to create an outflow of air from the outer space (2) and that the system (10) comprises an inlet (3) which allows for outdoor air to the outer space (2). Heat pump system (10) according to claim 2 or 3, characterized in that the first fl shaft (6) forms an integral part of the heat pump (5). Heat pump system (10) according to any one of the preceding claims, characterized in that the fate control means (3, 6, 7, 7a, 7b, 9) is arranged to direct a flow of lu fi contacted with the heat pump (5) and to allow distribution of In said air flow between a first outlet (7a). located inside the outer space (2), and a second outlet (7b) located outside the outer space (2). Friend pump system (10) according to claim 5, characterized in that the fate control means (6, 7, 7a, 7b, 9) comprises an air duct (7) for guiding the fate of air contacted with the heat pump (5) and a valve device (9 ) arranged to allow an adjustable distribution of said lult ult fate between a first outlet duct (Ya). which opens inside the outer space (2), and a second outlet channel (7b), which opens outside the outer space (2). Heat pump system (10) according to claims 3 and 6, characterized in that the first fl shaft (6) is located adjacent to the air duct (7). Heat pump system (10) according to one of the preceding claims, characterized in that the heat pump system (10) is arranged in connection with a building (4) and in that the heat pump system (10) comprises a connecting duct (15) arranged to conduct air between the outer space (2) and the building (4). Heat pump system (10) according to claim 8, 4, characterized in that the heat pump system (10) comprises means (16, 17) for regulating the air flow through the connecting duct (15). Heat pump system (10) according to one of the preceding claims, characterized in that the outer space (2) has walls and / or roofs (13) which at least partly consist of a material which is transparent to solar radiation. 10 1528 601 18 Heat pump system (10) according to one of the preceding claims, characterized in that the heat pump system (10) comprises an adjustable solar cutting device (14) adapted to be able to cut off the solar radiation (12) and thereby limit the heating of the outdoor air in the outer space (2). Friend pump system (10) according to one of the preceding claims, characterized in that the heat pump (5) is arranged to directly or indirectly deliver heat energy to one or more water systems (10) in a building (4), plant or process.